Systems for upgrading ventricle assist devices

ABSTRACT

Systems and devices for an updatable blood pump are disclosed herein. The blood pump can be part of a mechanical circulatory support system that can include a system controller and the blood pump. The blood pump can include a rotary motor and a control unit that can communicate with the system controller. The system controller can initiate the update process and can provide the update to the blood pump. Upon initiation of the update process, the control unit can stop the rotary motor. While the rotary motor is stopped, the blood pump can be updated. At the completion of the update, the rotary pump can be restarted.

CROSS-REFERENCES TO RELATED APPLICATIONS

This application is a divisional of U.S. patent application Ser. No.14/687,824 filed Apr. 15, 2015, now issued as U.S. Pat. No. 9,629,948,which application claims the benefit of U.S. Provisional Application No.61/979,843, filed Apr. 15, 2014, the entire contents each of which arehereby incorporated in their entirety for all purposes.

BACKGROUND

This application relates generally to mechanical circulatory supportsystems, and more specifically relates to control systems and methods,for an implantable blood pump.

Ventricular assist devices, known as VADs, are implantable blood pumpsused for both short-term (i.e., days, months) and long-term-applications(i.e., years or a lifetime) where a patient's heart is incapable ofproviding adequate circulation, commonly referred to as heart failure orcongestive heart failure. According to the American Heart Association,more than five million Americans are living with heart failure, withabout 670,000 new cases diagnosed every year. People with heart failureoften have shortness of breath and fatigue. Years of living with blockedarteries or high blood pressure can leave your heart too weak to pumpenough blood to your body. As symptoms worsen, advanced heart failuredevelops.

A patient suffering from heart failure, also called congestive heartfailure, may use a VAD while awaiting a heart transplant or as a longterm destination therapy. In another example, a patient may use a VADwhile recovering from heart surgery. Thus, a VAD can supplement a weakheart (i.e., partial support) or can effectively replace the naturalheart's function. VADs can be implanted in the patient's body andpowered by an electrical power source inside or outside the patient'sbody.

As VAD systems continue to develop, the prevalence of implantabletechnologies such as electronics continues to rise in its implementationin such systems. In particular, software updates to electronicsassociated with the VAD can be complicated and costly. For example, suchan update may require ex-plantation of the VAD, which requires anadditional surgery and further patient discomfort. Thus, new systems,methods, and devices are desired to facilitate efficient updates ofelectronics associated with a VAD.

BRIEF SUMMARY

The present invention provides new systems, methods, and devices whichcan advantageously allow for updates to implantable electronicsassociated with the VAD non-invasively or minimally invasively andwithout ex-plantation. For example, when a control unit is integrated ina VAD, there is no need to surgically replace or explant the blood pumpin order to upgrade the VAD. This is clearly advantageous from apatient's perspective who has heart failure, as this means no additionalsurgeries or recovery time, and for the healthcare system means lowercost of care. Further this invention provides a modality for access tothe latest technologies or features via the software upgrade. Theseupgrades may be transmitted via a hardwire or cable, or wirelessly. Theinventions of the present invention have numerous electro-mechanical andtherapeutic effects as described herein.

Embodiments of the present disclosure relate to a mechanical circulatorysupport system. The mechanical circulatory support system can include acontroller that can generate a signal initiating an update process andthat can transmit update information. The mechanical circulatory supportsystem can include an implantable blood pump that can be communicativelycoupled to the controller. The blood pump can include a rotor, and acontrol unit that can be communicatively coupled with the rotor. Thecontrol unit can include instructions to control the motion and positionof the rotor, to receive the signal initiating the update process, andto temporarily stop the rotor in response to the signal initiating theupdate process.

In some embodiments of the mechanical circulatory support system, therotor can include impeller blades. In some embodiments, the rotor can beradially levitated and driven by the control unit. In some embodiments,the control unit can include instructions to receive an update, toverify the update, and to store the update in place of an un-updatedapplication. In some embodiments, these can be performed while the rotoris temporarily stopped. In some embodiments, the control unit caninclude instruction to restart movement of the rotor after the updatehas been verified.

In some embodiments of the mechanical circulatory support system, therotor can be temporarily stopped for a period of less than 30 seconds,45 seconds, 1 minute, 2 minutes, 5 minutes, 10 minutes, or any other orintermediate length of time. It will be appreciated that the precedingtime ranges are important for clinical utility. In particular, beingable to perform the upgrade in a specified or predetermined time periodis important so that temporarily stopping the rotor does not result inany adverse effects on the patient who depends on operation of the VADto supplement or replace the pumping function of the heart. In someembodiments, the mechanical circulatory support system further includesa first application comprising parameters for rotor control and a secondapplication compassing parameters the rotor control. In someembodiments, the processor includes instructions to not erase one of thefirst and second applications during the update process.

In some embodiments of the mechanical circulatory support system, thecontrol unit can include flash memory that can include a plurality ofpartitions. In some embodiments, at least two of the partitions caninclude applications including parameters for controlling the operationof the blood pump. These parameters can define at least one of pumpspeed and a mode of operation, which can include, for example, pulsatileor non-pulsatile operation. In some embodiments, the controller can bean external controller that can include instructions to wirelesslytransmit update information or an external controller having a drivelinecoupled to the implantable pump to transmit update information.

In one aspect, the present disclosure relates to an implantable bloodpump. The implantable blood pump includes a rotor, and a control unitcommunicatively coupled with the rotor and including memory having aplurality of partitions. In some embodiments, a plurality ofapplications are loaded in at least some of the partitions. The controlunit can include instructions to control the motion and position of therotor, and temporarily stop the rotor in response to a signal initiatingan update process.

In some embodiments of the implantable blood pump, each of theapplications of the plurality of applications are uniquely associatedwith a datum and data identifying the time of the loading of each of theapplications into the partition. In some embodiments, the control unitcan include instructions to direct the control unit to select one of theapplications of the plurality of applications for replacement. In someembodiments, the one of the applications of the plurality ofapplications is selected for replacement if the datum associated withthe application does not match a datum generated by the control unit, orif the application data identifying the time of the loading of theapplication into the partition identifies the application as theearliest loaded application of the plurality of applications.

In some embodiments of the implantable blood pump, the plurality ofapplications can include a first application and a second application.In some embodiments, the first and second applications can includeinstructions for controlling the operation of the rotor. In someembodiments, the control unit can include instructions to not erase oneof the plurality of applications during the update process, and in someembodiments, the control unit can include instructions to direct therestart of movement of the rotor after the completion of the update.

In some embodiments of the implantable blood pump, the update iscompleted after one of: verification of the update, and a passage of apredetermined amount of time. In some embodiments, the rotor can berestarted according to one of the plurality of applications after thepassage of the predetermined amount of time.

In one aspect, the present disclosure relates to a method of updating animplantable blood pump. The method includes determining initiation of anupdate process within an implantable control unit included as part ofthe implantable blood pump, stopping the blood pump for a predeterminedamount of time, receiving an update while the blood pump is stopped, andrestarting the blood pump after the completion of the update process.

In some embodiments, the method can include verifying the update andreplacing an un-updated application with the update. In someembodiments, the method of updating an implantable blood pump caninclude identifying one of a plurality of un-updated applications forreplacement by the updated application. In some embodiments, theidentification of one of the plurality of un-updated applications caninclude generation of a datum, such as a checksum, based on the one ofthe un-updated applications. In some embodiments, the implantable bloodpump can be updated non-invasively or without ex-plantation. In someembodiments, receiving the update can include wirelessly receivingupdate information. In some embodiments, stopping the blood pump caninclude one of generating a stop signal and cutting power to a rotarymotor.

Further areas of applicability of the present disclosure will becomeapparent from the detailed description provided hereinafter. It shouldbe understood that the detailed description and specific examples, whileindicating various embodiments, are intended for purposes ofillustration only and are not intended to necessarily limit the scope ofthe disclosure.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is an illustration of a mechanical circulatory support systemimplanted in a patient's body.

FIG. 2 is an exploded view of certain components of the circulatorysupport system that are implanted in a patient's body.

FIG. 3 is an illustration of a blood pump in an operational positionimplanted in a patient's body.

FIG. 4 is a cross-sectional view of the blood pump of FIG. 3.

FIG. 5 is a partial cut-away perspective view of a stator of a bloodpump.

FIG. 6 is a schematic diagram of an overall communication architectureof the mechanical support system of FIG. 1.

FIG. 7 is a schematic diagram illustrating one embodiment of thearchitecture of the blood pump.

FIG. 8 is a flowchart illustrating one embodiment al the operation ofthe blood pump.

FIG. 9 is a schematic illustration of one embodiment of a configurationof a memory of the blood pump.

FIG. 10 is a flowchart illustrating one embodiment of a process forupdating the blood pump.

FIG. 11 is a flowchart illustrating one embodiment of a process forfailure detection for a blood pump update.

FIG. 12 is a swim lane diagram illustrating one embodiment ofcommunications between a system controller and a blood pump that occurduring an update process.

DETAILED DESCRIPTION

FIG. 1 is an illustration of a mechanical circulatory support system 10implanted in a patient's body 12. The mechanical circulatory supportsystem 10 comprises a implantable blood pump 14, ventricular cuff 16,outflow cannula 18, system controller 20, and power sources 22. Theimplantable blood pump 14 may comprise a VAD that is attached to an apexof the left ventricle, as illustrated, or the right ventricle, or bothventricles of the heart 24. The VAD may comprise a centrifugal (asshown) or axial flow pump as described in further detail herein that iscapable of pumping the entire output delivered to the left ventriclefrom the pulmonary circulation (i.e., up to 10 liters per minute).Related blood pumps applicable to the present invention are described mgreater detail below and in U.S. Pat. Nos. 5,695,471, 6,071,093,6,116,862, 6,186,665, 6,234,772, 6,264,635, 6,688,861, 7,699,586,7,976,271, 7,997,854, 8,007,254, 8,152,493, 8,652,024, and 8,668,473 andU.S. Patent Publication Nos. 2007/0078293, 2008/0021394, 2009/0203957,2012/0046514, 2012/0095281, 2011/0096364, 2013/0170970, 2013/0121821,and 2013/0225909, all of which are incorporated herein by reference forall purposes in their entirety. With reference to FIGS. 1 and 2, theblood pump 14 may be attached to the heart 24 via the ventricular cuff16 which is sewn to the heart 24 and coupled to the blood pump 14. Theother end of the blood pump 14 connects to the ascending aorta via theoutflow cannula 18 so that the VAD effectively diverts blood from theweakened ventricle and propels it to the aorta for circulation to thecrest of the patient's vascular system.

FIG. 1 illustrates the mechanical circulatory support system 10 duringbattery 22 powered operation. A driveline 26 which exits through thepatient's abdomen 28, connects the implanted blood pump 14 to the systemcontroller 20, which monitors system 10 operation. Related controllersystems applicable to the present invention are described in greaterdetail below and in U.S. Pat. Nos. 5,888,242, 6,991,595, 8,323,174,8,449,444, 8,506,471, 8,597,350, and 8,657,733 and U.S. PatentPublication Nos. 2005/0071001 and 2013/0314047, all of which areincorporated herein by reference for all purposes in their entirety. Thesystem may be powered by either one, two, or more batteries 22. It willbe appreciated that although the system controller 20 and power source22 are illustrated outside/external to the patient body, the driveline26, system controller 20 and/or power source 22 may be partially orfully implantable within the patient, as separate components orintegrated with the blood bump 14. Examples of such modifications arefurther described in U.S. Pat. No. 8,562,508 and U.S. Patent PublicationNo. 2013/0127253, all of which are incorporated herein by reference forall purposes in their entirety.

With reference to FIGS. 3 to 5, a left ventricular assist blood pump 100having a circular shaped housing 110 is implanted in a patient's bodywith a first face 111 of the housing 110 positioned against thepatient's heart H and a second face 113 of the housing 110 facing awayfrom the heart H. The first face 111 of the housing 110 includes aninlet cannula 112 extending into the left ventricle LV of the heart H.The second face 113 of the housing 110 has a chamfered edge 114 to avoidirritating other tissue that may come into contact with the blood pump100, such as the patient's diaphragm. To construct the illustrated shapeof the puck-shaped housing 110 in a compact form, a stator 120 andelectronics 130 of the pump 100 are positioned on the inflow side of thehousing toward first face 111, and a rotor 140 of the pump 100 ispositioned along the second face 113. This positioning of the stator120, electronics 130, and rotor 140 permits the edge 114 to be chamferedalong the contour of the rotor 140, as illustrated in at least FIGS.2-4, for example.

Referring to FIG. 4, the blood pump 100 includes a dividing wall 115within the housing 110 defining a blood flow conduit 103. The blood flowconduit 103 extends from an inlet opening 101 of the inlet cannula 112through the stator 120 to an outlet opening 105 defined by the housing110. The rotor 140 is positioned within the blood flow conduit 103. Thestator 120 is disposed circumferentially about a first portion 140 a ofthe rotor 140, for example about a permanent magnet 141. The stator 120is also positioned relative to the rotor 140 such that, in use, bloodflows within the blood flow conduit 103 through the stator 120 beforereaching the rotor 140. The permanent magnet 141 has a permanentmagnetic north pole N and a permanent magnetic south pole S for combinedactive and passive magnetic levitation of the rotor 140 and for rotationof the rotor 140. The rotor 140 also has a second portion 140 b thatincludes impeller blades 143. The impeller blades 143 are located withina volute 107 or the blood flow conduit such that the impeller blades 143are located proximate to the second face 113 of the housing 110.

The puck-shaped housing 110 further includes a peripheral wall 116 thatextends between the first time 111 and a removable cap 118. Asillustrated, the peripheral wall 116 is formed as a hollow circularcylinder having a width W between opposing portions of the peripheralwall 116. The housing 110 also has a thickness T between the first face111 and the second face 113 that is less than the width W. The thicknessT is from about 0.5 inches to about 1.5 inches, and the width W is fromabout 1 inch to about 4 inches. For example, the width W can beapproximately 2 inches, and the thickness T can be approximately 1 inch.

The peripheral wall 116 encloses an internal compartment 117 thatsurrounds the dividing wall 115 and the blood flow conduit 103, with thestator 120 and the electronics 130 disposed in the internal compartment117 about the dividing wall 115. The removable cap 118 includes thesecond face 113, the chamfered edge 114, and defines the outlet opening105. The cap 118 can be threadedly engaged with the peripheral wall 116to seal the cap 118 in engagement with the peripheral wall 116. The cap118 includes an inner surface 118 a of the cap 118 that defines thevolute 107 that is in fluid communication with the outlet opening 105.

Within the internal compartment 117, the electronics 130 are positionedadjacent to the first face 111 and the stator 120 is positioned adjacentto the electronics 130 on an opposite side of the electronics 130 fromthe first face 111. The electronics 130 include circuit boards 131 andvarious components carried on the circuit boards 131 to control theoperation of the pump 100 (e.g., magnetic levitation and/or drive of therotor) by controlling the electrical supply to the stator 120. Thehousing 110 is configured to receive the circuit boards 131 within theinternal compartment 117 generally parallel to the first face 111 forefficient use of the space within the internal compartment 117. Thecircuit boards also extend radially-inward towards the dividing wall 115and radially-outward towards the peripheral wall 116. For example, theinternal compartment 117 is generally sized no larger than necessary toaccommodate the circuit boards 131, and space for heat dissipation,material expansion, potting materials, and/or other elements used ininstalling the circuit boards 131. Thus, the external shape of thehousing 110 proximate the first face 111 generally fits the shape of thecircuits boards 131 closely to provide external dimensions that are notmuch greater than the dimensions of the circuit boards 131.

With continued reference to FIGS. 4 and 5, the stator 120 includes aback iron 121 and hole pieces 123 a-123 f arranged at intervals aroundthe dividing wall 115. The back iron 121 extends around the dividingwall 115 and is formed as a generally flat disc of a ferromagneticmaterial, such as steel, in order to conduct magnetic flux. The backiron 121 is arranged beside the control electronics 130 and provides abase for the pole pieces 123 a-123 f.

Each of the pole piece 123 a-123 f is L-shaped and has a drive coil 125for generating an electromagnetic field to rotate the rotor 140. Forexample, the pole piece 123 a has a first leg 124 a that contacts theback iron 121 and extends from the back iron 121 towards the second thee113. The pole piece 123 a may also have a second leg 124 b that extendsfrom the first leg 124 a through an opening of a circuit board 131towards the dividing wall 115 proximate the location of the permanentmagnet 141 of the rotor 140. In an aspect, each of the second legs 124 bof the pole pieces 123 a-123 f is sticking through an opening of thecircuit board 131. In an aspect, each of the first legs 124 a of thepole pieces 123 a-123 f is sticking through an opening of the circuitboard 131. In an aspect, the openings of the circuit board are enclosingthe first legs 124 a of the pole pieces 123 a-123 f.

In a general aspect, the implantable blood pump 100 may include a Hallsensor that may provide an output voltage, which is directlyproportional to a strength of a magnetic field that is located inbetween at least one of the pole pieces 123 a-123 f and the permanentmagnet 141, and the output voltage may provide feedback to the controlelectronics 130 of the pump 100 to determine if the rotor 140 and/or thepermanent magnet 141 is not at its intended position for the operationof the pump 100. For example, a position of the rotor 140 and/or thepermanent magnet 141 may be adjusted, e.g. the rotor 140 or thepermanent magnet 141 may be pushed or pulled towards a center of theblood flow conduit 103 or towards a center of the stator 120.

Each of the pole pieces 123 a-123 f also has a levitation coil 127 forgenerating an electromagnetic field to control the radial position ofthe rotor 140. Each of the drive coils 125 and the levitation coils 127includes multiple windings of a conductor around the pole pieces 123a-123 f. Particularly, each of the drive coils 125 is wound around twoadjacent ones the pole pieces 123, such as pole pieces 123 d and 123 e,and each levitation coil 127 is wound around a single pole piece. Thedrive coils 125 and the levitation coils 127 are wound around the firstlegs of the pole pieces 123, and magnetic flux generated by passingelectrical current though the coils 125 and 127 during use is conductedthrough the first legs and the second legs of the pole pieces 123 andthe back iron 121. The drive coils 125 and the levitation coils 127 ofthe stator 120 are arranged in opposing pairs and are controlled todrive the rotor and to radially levitate the rotor 140 by generatingelectromagnetic fields that interact with the permanent magnetic poles Sand N of the permanent magnet 141. Because the stator 120 includes boththe drive coils 125 and the levitation coils 127, only a single statoris needed to levitate the rotor 140 using only passive and activemagnetic forces. The permanent magnet 141 in this configuration has onlyone magnetic moment and is formed from a monolithic permanent magneticbody 141. For example, the stator 120 can be controlled as discussed inU.S. Pat. No. 6,351,048, the entire contents of which are incorporatedherein by reference for all purposes. The control electronics 130 andthe stator 120 receive electrical power from a remote power supply via acable 119 (FIG. 3). Further related patents, namely U.S. Pat. Nos.5,708,346, 6,053,705, 6,100,618, 6,222,290, 6,249,067, 6,278,251,6,351,048, 6,355,998, 6,634,224, 6,879,074, and 7,112,903, all of whichare incorporated herein by reference for all purposes in their entirety.

The rotor 140 is arranged within the housing 110 such that its permanentmagnet 141 is located upstream of impeller blades in a location closerto the inlet opening 101. The permanent magnet 141 is received withinthe blood flow conduit 103 proximate the second leas 124 b of the polepieces 123 to provide the passive axial centering force thoughinteraction of the permanent magnet 141 and ferromagnetic material ofthe pole pieces 123. The permanent magnet 141 of the rotor 140 and thedividing wall 115 form a gap 108 between the permanent magnet 141 andthe dividing wall 115 when the rotor 140 is centered within the dividingwall 115. The gap 108 may be from about 0.2 millimeters to about 2millimeters. For example, the gap 108 is approximately 1 millimeter. Thenorth permanent magnetic pole N and the south permanent magnetic pole Sof the permanent magnet 141 provide a permanent magnetic attractiveforce between the rotor 140 and the stator 120 that acts as a passiveaxial centering force that tends to maintain the rotor 140 generallycentered within the stator 120 and tends to resist the rotor 140 frommoving towards the first face 111 or towards the second thee 113. Whenthe gap 108 is smaller, the magnetic attractive force between thepermanent magnet 141 and the stator 120 is greater, and the gap 108 issized to allow the permanent magnet 141 to provide the passive magneticaxial centering force having a magnitude that is adequate to limit therotor 140 from contacting the dividing wall 115 or the inner surface 118a of the cap 118. The rotor 140 also includes a shroud 145 that coversthe ends of the impeller blades 143 facing the second face 113 thatassists in directing blood flow into the volute 107. The shroud 145 andthe inner surface 118 a of the cap 118 form a gap 109 between the shroud145 and the inner surface 118 a when the rotor 140 is levitated by thestator 120. The gap 109 is from about 0.2 millimeters to about 2millimeters. For example, the gap 109 is approximately 1 millimeter.

As blood flows through the blood flow conduit 103, blood flows through acentral aperture 141 a formed through the permanent magnet 141. Bloodalso flows through the gap 108 between the rotor 140 and the dividingwall 115 and through the gap 109 between the shroud 145 and the innersurface 108 a of the cap 118. The gaps 108 and 109 are large enough toallow adequate blood flow to limit clot formation that may occur if theblood is allowed to become stagnant. The gaps 108 and 109 are also largeenough to limit pressure forces on the blood cells such that the bloodis not damaged when flowing through the pump 100. As a result of thesize of the gaps 108 and 109 limiting pressure forces on the bloodcells, the gaps 108 and 109 are too large to provide a meaningfulhydrodynamic suspension effect. That is to say, the blood does not actas a bearing within the gaps 108 and 109, and the rotor is onlymagnetically-levitated. In various embodiments, the gaps 108 and 109 aresized and dimensioned so the blood flowing through the gaps forms a filmthat provides a hydrodynamic suspension effect. In this manner, therotor can be suspended by magnetic forces, hydrodynamic forces, or both.

Because the rotor 140 is radially suspended by active control of thelevitation coils 127 as discussed above, and because the rotor 140 isaxially suspended by passive interaction of the permanent magnet 141 andthe stator 120, no rotor levitation components are needed proximate thesecond face 113. The incorporation of all the components for rotorlevitation in the stator 120 (i.e., the levitation coils 127 and thepole pieces 123) allows the cap 118 to be contoured to the shape of theimpeller blades 143 and the volute 107. Additionally, incorporation ofall the rotor levitation components in the stator 120 eliminates theneed for electrical connectors extending from the compartment 117 to thecap 118, which allows the cap to be easily installed and/or removed andeliminates potential sources of pump failure.

In use, the drive coils 125 of the suitor 120 generates electromagneticfields through the pole pieces 123 that selectively attract and repelthe magnetic north pole N and the magnetic south pole S of the rotor 140to cause the rotor 140 to rotate within stator 120. For example, theHall sensor may sense a current position of the rotor 140 and/or thepermanent magnet 141, wherein the output voltage of the Hall sensor maybe used to selectively attract and repel the magnetic north pole N andthe magnetic south pole S of the rotor 140 to cause the rotor 140 torotate within stator 120. As the rotor 140 rotates, the impeller blades143 force blood into the volute 107 such that blood is forced out of theoutlet opening 105. Additionally, the rotor draws blood into pump 100through the inlet opening 101. As blood is drawn into the blood pump byrotation of the impeller blades 143 of the rotor 140, the blood flowsthrough the inlet opening 101 and flows through the control electronics130 and the suitor 120 toward the rotor 140. Blood flows through theaperture 141 a of the permanent magnet 141 and between the impellerblades 143, the shroud 145, and the permanent magnet 141, and into thevolute 107. Blood also flows around the rotor 140, through the gap 108and through the gap 109 between the shroud 145 and the inner surface 118a of the cap 118. The blood exits the volute 107 through the outletopening 105, which may be coupled to an outflow cannula.

FIG. 6 is a schematic diagram of an overall communication architectureof the mechanical support system of FIG. 1. A driveline couples theimplanted blood pump 100 to the system controller 20, which monitorssystem operation via various software applications. The blood pump 100itself also includes several software applications that are executableby the on board electronics 130 (e.g., processors) for variousfunctions, such as to control radial levitation and/or drive of therotor of the pump 100 during operation. The system controller 20 may inturn be coupled to batteries 22 or a power module 30 that connect to anAC electrical outlet. The system controller 20 may also include anemergency backup battery (EBB) to power the system (e.g., when thebatteries 22 are depleted) and a membrane overlay, including bluetoothcapabilities for wireless data communication. An external computerhaving a system monitor 32 that is configurable by an operator, such asclinician or patient, may further be coupled to the circulatory supportsystem for configuring the system controller 20, implanted blood pump100, and/or patient parameters, updating software on the systemcontroller 20 and/or implanted blood pump 100, monitoring systemoperation, and/or as a conduit for system inputs or outputs.

In some embodiments, the software applications of the blood pump 100 caninclude, for example, an initial program loader (IPL), loader software,and/or application software. In some embodiments, the IPL can beconfigured to select and load one or several software applicationscorresponding to one or several modes of operation of the blood pump100. In some embodiments, these one or several modes of operation of theblood pump 100 can include an operation mode, a test mode, a fault mode,or the like. The selecting and loading of one or several softwareapplications corresponding to one or several modes of operation of theblood pump 100 can include, for example, selecting and loading one orseveral of the loader software and/or the application software. In someembodiments, the IPL can include information relating to one or severalfailsafe and/or fault protocols that can be used by the blood pump 100.Some of the failsafe and/or fault protocols will be discussed at lengthbelow.

The loader software, can, in some embodiments, be configured to directthe operation of the blood pump 100 during the loading of one or severalsoftware applications onto the blood pump 100. This direction of theoperation of the blood pump 100 during loading of one or severalsoftware applications can include, for example, directing the blood pump100 to stop operation during the loading of the one or several softwareapplications or directing the blood pump 100 to continue operationduring the loading of the one or several software applications accordingto a previously received software application. These one or severalsoftware applications can include, for example, one or severalapplication softwares, one or several IPL applications, or the like. Insome embodiments, the loader software can prescribe one or severalprocesses for updating and/or loading one or several softwareapplications onto the blood pump 100. These processes and associatedfailsafes will be discussed in greater details below.

The application software can include one or several parameters fordirecting the pumping operation of the blood pump 100. In someembodiments, the application software can comprise one of a clinicalapplication software which can be configured to control the operation ofthe blood pump 100 when implanted in a patient, and in some embodiments,the application software can comprise a production software that can beconfigured to control the operation of the blood pump 100 duringproduction and/or testing of the blood pump 100.

In some embodiments, these parameters can specify a control or controlregimen for the position and/or motion of the rotor 140. For example,these parameters can specify the aspects of the levitation controland/or rotation control of the rotor 140.

In some embodiments, the parameters of the application software canspecify, for example a desired performance of the blood pump 100 and/orone or several desired performance parameters, such as, for example, adesired pump speed, and desired pumped flow rate, a pulse generation, orthe like. In some embodiments, these parameters can be actively used tocontrol the operation of the blood pump 100, and in same embodimentsthese parameters can be stored during normal operation of the blood pump100 and used as part of one or several failsafe and/or fault protocols.In some embodiments, the parameters of the application software canspecify the generation and/or collection of data from the blood pump 100and/or interfacing of the blood. pump 100 to other components of themechanical circulatory support system 10.

In some embodiments, the application software can comprises a firstapplication software containing parameters relating to the currentoperation of the blood pump, and in some embodiments, the applicationsoftware can comprise a second application software containingparameters unrelated to the current operation of the blood pump 100. Inone embodiment, for example, the blood pump 100 can comprise the secondapplication software as a backup to the first application software. Insome embodiments, the first application software can be identical to thesecond application software, and in some embodiments, the firstapplication can be different than the second application software.

FIG. 7 is a schematic diagram illustrating one embodiment of the bloodpump 100. As seen in FIG. 7, the blood pump 100 includes electronics 130and a rotary motor 200, which rotary motor 200 can include the stator120 and the rotor 140. As seen in FIG. 7, the electronics 130 caninclude a control unit 202 that can control the operations of the bloodpump 100 and can interact with other components of the mechanicalcirculatory support system 10. As shown, the control unit 202 cancommunicate with the rotary motor 200 and with the communications module208. In some embodiments, the control unit 202 and electronics 130 canbe located in the same implantable housing 110 as the rotary motor 200,and in some embodiments, the control unit and electronics can be locatedin a separate implantable housing than the blood pump housing 110. Forexample, the system controller 20 can be located in an implantablehousing, and the control unit 202 and electronics 130 can be co-locatedin that same implantable housing in a fully implantable transcutaneousenergy transfer system.

The control unit 202 can include a processor 204. The processor 204 canprovide instructions to, and receive information from the othercomponents of the blood pump 100 and/or from the other components of themechanical circulatory support system 10. The processor 204 can actaccording to stored instructions, which stored instructions can belocated in memory 206 associated with the processor 204 and/or in othercomponents of the blood pump 100 and/or of the mechanical circulatorysupport system 10. The processor 204 can comprise a microprocessor, suchas a microprocessor from Intel® or Advanced Micro Devices, Inc.®, or thelike.

In some embodiments, the stored instructions directing the operation ofthe processor 204 may be implemented by hardware, software, scripting,languages, firmware, middleware, microcode, hardware descriptionlanguages, and/or any combination thereof. When implemented in software,firmware, middleware, scripting language, and/or microcode, the programcode or code segments to perform the necessary tasks may be stored in amachine readable medium such as a storage medium. A code segment ormachine-executable instruction may represent a procedure, a function, asubprogram, a program, a routine, a subroutine, a module, a softwarepackage, a script, a class, or any combination of instructions, datastructures, and/or program statements. A code segment may be coupled toanother code segment or a hardware circuit by passing and/or receivinginformation, data, arguments, parameters, and/or memory contents.Information, arguments, parameters, data, etc. may be passed, forwarded,or transmuted via any suitable means including memory sharing, messagepassing, token passim network transmission, etc.

As seen in FIG. 7, the control unit 202 includes a memory 206. In thisembodiment, the memory 206 is the storage medium containing the storedinstructions. The memory 206 may represent one or more memories forstoring data, including read only memory (ROM), random access memory(RAM), magnetic RAM, core memory, magnetic disk storage mediums, opticalstorage mediums, flash memory devices and/or other machine readablemediums for storing information. In some embodiments, the memory 206 maybe implemented within the processor 204 or external to the processor204. In some embodiments, the memory 206 can be any type of long term,short term, volatile, nonvolatile, or other storage medium and is not tobe limited to any particular type of memory or number of memories, ortype of media upon which memory is stored. In some embodiments, thememory 206 can include, for example, one or both of volatile andnonvolatile memory. In one specific embodiment, the memory 206 caninclude a volatile portion such as RAM memory, and a nonvolatile portionsuch as flash memory.

In some embodiments, the memory 206 can be divided into one or severalpartitions. In one embodiment in which the memory 206 contains aplurality of software applications, the memory 206 can be divided into aplurality of partitions so as to be, for example, in a one to onerelationship with the number of software applications in the pluralityof software applications. In some embodiments, some or all of thesoftware applications stored in the memory 206 can be stored in a uniqueone of the partitions in the memory 206. In one embodiment, in which thememory 206 comprises a volatile portion and a nonvolatile portion, thepartitions can be created in one or both of the volatile portion and thenonvolatile portion. Specifically, in one embodiment in which the memory206 comprises RAM and flash memory, the flash memory can be divided intoa plurality of partitions. In some embodiments, the plurality ofsoftware applications can be stored in the plurality of partitions inthe flash memory.

As described above, the processor 204 can send information and/orsignals with and/or receive information and/or signals from thecommunications module 208. The communications module 208 can includefeatures configured to send and receive information, including, forexample, an antenna, a transmitter, receiver, or any other feature thatcan send and receive information. The communications module 208 cancommunicate via a wired or wireless link with, for example, the systemcontroller 20 and/or the rotary motor 200. In some embodiments, thecommunications module 208 can communicate via cellular networks, WLANnetworks, or any other wireless network. In some embodiments, the bloodpump 100 can be configured to generate a signal in response to some orall communications received from the system controller 20, and/or to notgenerate a signal to the system controller 20 unless a signal from thesystem controller 20 has been first received by the blood pump 100.

FIG. 8 is a flow-chart illustrating one embodiment of a process 220 foroperation of the blood pump 100. The process 220 can be performed tostart the pumping of the blood pump 100, and can be performed usingcomponents of the blood pump 100 including, for example, the controlunit 202. The process 220 begins, in some embodiments, at block 222wherein the blood pump 100 is powered up. In some embodiments, thepowering up the blood pumped 100 can include the receipt of power by theblood pump 100 from one of the batteries 22 and/or other power source.In some embodiments, after the blood pump 100 is powered, the process220 proceeds to block 224 wherein the is run. In some embodiments, therunning of the IPL can include, for example, retrieval of the IPL fromthe memory 206 and the execution of IPL instructions by the processor204.

After the IPL is running, the process 220 proceeds to block 226 whereinthe IPL selects one or several software applications for control of theblood pump 100. In some embodiments, the one or several softwareapplications can be selected from the memory 206. After the one orseveral software applications have been selected, the process 220proceeds to block 228 wherein the IPL determines the validity of the oneor several selected software applications. In some embodiments, this caninclude the determination of the functionality of the one or severalsoftware applications and/or the detection of any faults and/or errorsin, or caused by the one or several selected software applications.

After the IPL has determined the validity of the one or several selectedsoftware applications, the process 220 proceeds to block 230 wherein theIPL retrieves the one or several selected software applications from thememory 206 and starts the one or several selected software applications.As specifically seen in FIG. 8, the IPL can, for example, and asdepicted in block 232, copy a software application stored in one of thepartitions of the memory 206, such as, for example, a second partitionin the flash memory, to the RAM and start the copied softwareapplication. Similarly, in one embodiment, the IPL can, and as depictedin block 234, copy a software application stored in one of thepartitions of the memory, such as, for example, a third partition in theflash memory, to the RAM and start the copied software application. Insome embodiments, the starting of the software application stored in oneof the second partition and the third partition can result in thestarting of the blood pump 100, the starting of the movement of therotor 140, and the starting of the associated pumping of blood. In oneembodiment, the IPL can, as depicted in block 236, start the loadersoftware. In some embodiments, the loader software can be started as anearly step in the update of the blood pump 100.

FIG. 9 is a schematic illustration of one embodiment of memory 206 ofthe blood pump 100. As depicted in FIG. 9, the memory 206 of the bloodpump can include volatile memory, such as RAM 260 and non-volatilememory such as flash 262. The flash 262 can be divided into severalpartitions. In the embodiment depicted in FIG. 9, the flash 262 isdivided into partition 0 264-A, partition 1 264-B, partition 2 264-C,partition 3 264-D, partition 4 264-E, and partition 5 264-F. As seen inFIG. 9, some of the partitions 264-A-264-F contain a softwareapplication. Specifically, partition 0 264-A contains the IPL and loadersoftware, partition 1 264-B contains a backup copy of the IPL and loadersoftware, and partition 2 264-C and partition 3 264-D each containapplication software and application software information. In someembodiments, partition 2 264-C and partition 3 264-D correspond to thesecond and third memory partitions, respectively.

In some embodiments, and as seen in FIG. 9, partition 2 264-C andpartition 3 264-D are each divided into first and second portions. Inthe embodiment depicted in FIG. 9, the first portion of partition 2264-C contains first application software 266 and the first portion ofpartition 3 264-D contains second application software 268. In theembodiment depicted in FIG. 9, the second portion of partition 2 264-Ccontains first application software information 270 and the secondportion of partition 3 264-D contains second application softwareinformation 272. In some embodiments, the application softwareinformation can include, a datum that can be used to identify/verify theapplication software, such as, for example, a hash or a checksum andinformation either absolutely or relatively identifying the time and/ordate that the application software was loaded on the blood pump 100.

FIG. 10 is a flowchart illustrating one embodiment of a process 300 forupdating one or several software applications of the blood pump 100. Insome embodiments, this process 300 can be performed by the implantedblood pump 100, and can be non-invasively performed and/or performedwithout ex-plantation of the blood pump 100. In one embodiment, theprocess 300 begins at block 302 wherein an update initiation signal isreceived. In some embodiments, the update initiation signal can begenerated by the system controller 20, and can be communicated to theblood pump 100 via, for example, the communications module 208. In oneembodiment, the update initiation signal can be wirelessly communicatedfrom the system controller 20 to the blood pump 100 via thecommunications module 208. In some embodiments, and in response to thereceipt of the update initiation signal, the steps of process 220 can beperformed, and the IPL can select and start the software loader asindicated in block 236.

After the update initiation signal has been received, the process 300proceeds to block 304 wherein a timer is started. In some embodiments,the timer can be an integral component of the control unit 202 and cantrack one or several times and/or time periods. In some embodiments, thetimer can track the total lapsed time of the update. The timer can beused to trigger one or several errors if an action or process does notoccur or terminate within a predetermined time period. In oneembodiment, for example, an error can be triggered if the update lastslonger than a certain time period such as, for example, 5 seconds, 10seconds, 30 seconds, one minute, two minutes, three minutes, fiveminutes, 10 minutes, and/or any other or intermediate time period.

In some embodiments, the timer can track the amount of time betweenevents, such as, for example, between communications from the systemcontroller 20. In one embodiment, for example, the system controller 20can periodically communicate with the blood pump 100 during the durationof the update. In one embodiment, for example, an error can be triggeredif a communication is not received from the system controller 20 withina designated time period, which time period can be, for example, 1second, 2 seconds, 5 seconds, 10 seconds, 20 seconds, or any other orintermediate timer period.

After the update initiation signal has been received, the process 300proceeds to block 306 wherein the blood pump 100 is stopped. In someembodiments, the blood pump 100 and/or rotary motor 200 can be stoppedby the control unit 202. The control unit 202 can generate a stop signaland send the stop signal to the stator 120 if the blood pump 100, and/orcan cut power to the stator 120 of the blood pump 100. In someembodiments, the power can be selectively cut and/or decreased, andspecifically, the power provided to the stator 120 and/or components ofthe stator 120 can be selectively cut and/or decreased to thereby stopthe motion of the rotor 140. In some embodiments, the stopping of theblood pump 100 can be performed according to one or several stoppingalgorithms contained in the memory 206 of the control unit 202.

After the pump has been stopped, the process 300 proceeds to block 308wherein the update application is received. In some embodiments, theupdate application can be received from the system controller 20 via thecommunications module 208. The update application can includeapplication software and application software information associatedwith and/or corresponding to the application software.

After the update application has been received, the process 300 proceedsto block 310, wherein the application for update is identified. In someembodiments, the application for update is the application that is beingreplaced by the update application. The application for update can beone of the IPL, the loader software, and/or one of the applicationsoftwares. In some embodiments, as the memory may include a plurality ofthe IPL, the loader software, and/or of the application softwares, theidentification of the application for update can include selecting oneof the IPL, the loader software, and/or the application softwares. Anyof the IPL, the loader software, and/or the application softwares thatare evaluated for selection as the application for update are referredto herein as the “potential update applications.”

In some embodiments in which the application software is uploaded, thepotential update applications can include the first application software266 and the second application software 268. In some embodiments, inwhich the first and second application softwares 266, 268 are thepotential update applications, one of the first and second applicationsoftwares 266, 268 can be selected as the application for update. Insome embodiments in which one of the IPL and/or the software loader arethe potential update applications, the potential update applications caninclude the copies of the IPL, and/or the software loader stored inpartition 0 264-A and partition 1 264-B. In some embodiments, one ofthese copies can be selected as the application for update.Advantageously, by selecting one of the potential update applications asthe application for update, the other of the potential updateapplications is/are unaffected by the update process, and can be used asa failsafe in the event that the update is not successful. In such anevent, the other of the update applications can be used to controloperation of the blood pump 100, and can, in some embodiments, be copiedinto the partition that contained the selected one of the potentialupdate applications. Similarly, in some embodiments in which one of thefirst and second application softwares 266, 268 is selected for update,the other of the first and second application softwares 266, 268 isunaffected by the update process, and can be used as a failsafe in theevent that the update is not successful.

In some embodiments, one of the potential update applications can beselected as the application for update. In some embodiments, theapplication for update can be selected based on the amount of timepassed since the uploading of each of the potential update applicationsand/or errors in one or more of the potential update applications.

In some embodiments, the identification of the application for updatecan include determining the indicated placement for the updateapplication and determining the type of the update application. In someembodiments, the indicated placement for the update application caninclude identification of one or several partitions in which the updateapplication may be stored, in other words, the partitions currentlycontaining the potential update applications. In some embodiments, theindicated placement for the update application can be compared to thetype of the update application to determine if the indicated placementcorresponds with the type of the update application. This can occur, forexample if the indicated placement corresponds to a partition designatedfor one of the IPL and/or loader software, and the type of updateapplication corresponds to an application software. In some embodiments,if the indicated placement does not correspond with the type of theupdate application, the process 300 can terminate, the update canterminate, an error can be identified, and/or the pumping of the bloodpump 100 can be restarted.

In some embodiments, if the indicated placement corresponds with thetype of the update application, the identification of the applicationfor update can include identifying errors in one or several of thepotential update applications. In some embodiments, these errors can beidentified by generating a datum for each of the potential updateapplications and comparing the generated datums to a stored datum forthe corresponding one of the potential update applications from whichthe datum was generated. If the generated datum matches the storeddatum, then no error is detected. Conversely, a discrepancy between thegenerated datum and the stored datum can indicate an error in theapplication associated with the datums. In some embodiments, theexistence of a discrepancy between the generated datum and the storeddatum associated with a software application can result in the selectionof that software application for update. Thus, in one embodiment, asoftware application containing an error as evidenced by a discrepancybetween the generated datum and the stored datum can be replaced via theupdate process, thereby facilitating the maintenance of error freesoftware applications and error free operation of the blood pump 100.

In some embodiments, if no discrepancy is detected between the generateddatums and the stored datums for the potential update applications, theidentification of the application for update can include comparison ofthe time elapsed between the uploading of the potential updateapplications. In some embodiments, this comparison can be based onportions of the application software information identifying the time ofupload of an associated software application. In one embodiment, forexample, the one of the potential update applications uploaded earliestcan be selected as the application for update.

After the application for update has been identified, the process 300proceeds to block 312, wherein the application for update is deleted. Insome embodiments, the application for update can be deleted from thepartition in which it is stored. In some embodiments, the deletion ofthe application for update can include the deletion of the applicationsoftware information associated with the application for update.

After the application tor update has been deleted, the process 300proceeds to block 314, wherein the update application is verified. Insome embodiments, this verification can include generation of a datumfor the update application and comparison of the generated datum with adatum received with update application in block 303. In someembodiments, the received datum can be, for example, part of theapplication software information received in block 308. If it isdetermined that the generated datum does not match the received datum,an error can be identified, the update can be terminated, and thepumping of the blood pump 100 can be restarted. In some embodiments, thepumping of the blood pump 100 can be restarted using the other of thepotential update applications that is unaffected by the update process.

If it is determined that the generated datum matches the datum receivedwith the update application in block 308, then the process proceeds toblock 316, wherein the update application is stored. In someembodiments, the update application can be stored in the partition inwhich the application for update was stored. In some embodiments, thestorage of the update application in the appropriate partition caninclude the storage of the application software information associatedwith the update application in that same partition. In some embodiments,after the update application has been stored, the verification of block314 can, in some embodiments, be repeated to validate the proper storageof the application.

After the update application has been stored, the process 300 proceedsto block 318, wherein the pumping of the blood pump 100 is restarted. Insome embodiments, the pumping of the blood pump 100 can be restarted,and the blood pump 100 can be operated according to the parameters andinstructions contained in the update application.

FIG. 11 is a flowchart illustrating one embodiment of a process 400 forfailure detection in a blood pump update. In some embodiments, theprocess 400 can be performed simultaneously with the process 300depicted in FIG. 10. In some embodiments, this process 400 can beperformed by the control unit 202. The process 400 begins at block 302wherein an update initiation signal is received. In some embodiments,the update initiation signal can be generated by the system controller20, and can be communicated to the pump electronics 130 via, forexample, the communications module 208. In one embodiment, the updateinitiation signal can be wirelessly communicated from the systemcontroller 20 to the pump electronics 130 via the communications module208. In some embodiments, and in response to the receipt of the updateinitiation signal, the steps of process 220 can be performed, and theIPL can start the software loader as indicated in block 236.

After the update initiation signal has been received, the process 400proceeds to block 402, wherein a timer is started. In some embodiments,the timer can be an integral component or function of the control unit202 and can track one or several times and/or time periods. In someembodiments, the timer can track the total lapsed time of the update,and/or the timer can track the amount of time between events such as,for example, between communications received from the system controller20.

After the timer has been started, the process 400 proceeds to block 404,wherein communication period information is received. In someembodiments, the communication period can identify, for example, ananticipated and/or desired frequency with which communications areexpected from the system controller 20. In one embodiment, for example,the identification of the communication period can indicate that acommunication is expected from the system controller 20 every 10seconds, every five seconds, every second, twice a second, five times asecond, ten times a second, and/or any other or intermediate frequency.

In some embodiments, the communication period can identify the maximumlength of time that can pass without receiving a communication from thesystem controller 20 before an error is identified and/or an alarm istriggered. In one embodiment, for example, this amount of time can beone minute, thirty seconds, ten seconds, five seconds, one second, 0.5seconds, or any other or intermediate length of time. The communicationperiod information can identify the anticipated frequency ofcommunication and/or the maximum allowable length of time betweencommunications.

After the communication period identification has been received, theprocess 400 proceeds to block 406, wherein the end of the communicationperiod is defined and/or determined. This end can be determined with acombination of the time of the last received communication and thecommunication period information. After the end of the communicationperiod has been defined, the process 400 proceeds to decision state 408,wherein it is determined if a communication was received from the systemcontroller 20 by the end of the communication period. If it isdetermined that a communication was not received, then the process 400proceeds to block 410, wherein an error is triggered, to block 412,wherein the update process is cancelled, and to block 414, wherein thepumping of the blood pump 100 is restarted.

If it is determined that the communication has been received, then theprocess 400 proceeds to block 416, wherein the upload time limit isreceived. In some embodiments, the steps of blocks 404 through 406 canbe repeated until the update process has terminated.

Returning again to block 416, in some embodiments, the upload time limitcan define a maximum duration for the completion of the upload process.In some embodiments, the upload time limit can identify a maximum timeof 30 seconds, 1 minute, 2 minutes, 3 minutes, 4 minutes, 4 minutes and50 seconds, 5 minutes, 10 minutes, 20 minutes, and/or any other orintermediate time. In some embodiments, the upload time limit can beselected based on physical attributes of a human body such as, forexample, safe durations of time for restricted blood flow. In someembodiments, the upload time limit can be the same for multiplepatients, and in some embodiments, the upload time limit can becustomized for a patient based on a patient attribute such as, forexample, health, heart function, bodyweight, and/or the like.

After the upload time limit has been received, the process 400 proceedsto block 418 wherein the end of the time period defined by the uploadtime limit is identified. After the end of the time period defined bythe upload time limit has been identified, the process 400 proceeds todecision state 420, wherein it is determined if the upload is complete.In some embodiments, this determination can include determining whetherthe pumping of the blood pump 100 has been restarted. If the upload iscomplete, then the process 400 can proceed to block 414, wherein thepumping of the blood pump 100 is restarted. If the upload is notcomplete, then the process 400 proceeds to block 410, wherein an erroris triggered, to block 412, wherein the update process is cancelled, andto block 414, wherein the pumping of the blood pump 100 is restarted.

FIG. 12 is a swim lane diagram illustrating one embodiment of an updateprocess 450 and the communications between the system controller 20 andthe blood pump 100 that occur during the update process 450. The processbegins at block 452 in the auto baud detection phase. In this phase, thecommunication rate between the system controller 20 (also referred to asthe external controller) and the blood pump 100 (indicated in FIG. 12 as“Loader”) is determined.

After the auto baud detection phase has been completed, the process 450proceeds to the partition erase phase 454. In some embodiments, thecommunications in the partition erase phase 454 can include a commandfrom the system controller 20 to erase the contents of one or severalpartitions, and a confirmation from the blood pump 100 when the contentsof one or several partitions have been erased.

After the partition erase phase has been completed, the process 450proceeds to the programming phase 456. In some embodiments, the updateapplication can be transferred to the blood pump 100 during theprogramming phase 456 via one or several communications from the systemcontroller 20. In some embodiments, the programming phase 456 caninclude the storing of the update application in the partition havingerased contents.

After the programming phase has been completed, the process 450 proceedsto the verification phase 459 wherein the accuracy of the updateapplication is verified via the generation of a datum for the updateapplication and the comparison of the generated datum to a receiveddatum. In some embodiments, the verification phase 458 can be initiatedby a command from the system controller 20 to verify the updateapplication and a reply from the blood pump 100 indicating thecompletion of the verification and/or the results of the verification.

After the verification phase has been completed, the process 450proceeds to the finalization phase 460, wherein the stored updateapplication is finalized. In some embodiments, this can include are-verification of the update application by the generation of a newdatum for the update application and the comparison of the generated newdatum to a received datum. In some embodiments, this can further includethe creation of data indicating the time of storing/loading of theupdate application on the blood pump 100. In some embodiments, thefinalization phase can include a command from the system controller 20to exit the software loader.

After the finalization phase has been completed, the process 450proceeds to the failsafe and exit phase, wherein the success of theupload is evaluated. In some embodiments, if it is determined that theupload was not successful, either during the failsafe and exit phase, orduring any other phase indicated in process 450, one or several failsafemeasures can be run, which measures can include termination of theupdate process and restarting of the pumping of the blood pump 100. Ifit is determined that the update was successful, then the pumping of theblood pump 100 can be restarted.

In the foregoing specification, the invention is described withreference to specific embodiments thereof, but those skilled in the artwill recognize that the invention is not limited thereto. Variousfeatures and aspects of the above-described invention can be usedindividually or jointly. Further, the invention can be utilized in anynumber of environments and applications beyond those described hereinwithout departing from the broader spirit and scope of thespecification. The specification and drawings are, accordingly, to beregarded as illustrative rather than restrictive. It will be recognizedthat the terms “comprising,” “including,” and “having,” as used herein,are specifically intended to be read as open-ended terms of art.

What is claimed is:
 1. A mechanical circulatory support systemcomprising: a controller configured to generate a signal initiating anupdate process and configured to transmit update information; and animplantable blood pump communicatively coupled to the controller, theblood pump comprising: a rotor; and a control unit communicativelycoupled with the rotor and configured to: control the motion andposition of the rotor; receive the signal initiating the update process;and temporarily stop the rotor in response to the signal initiating theupdate process.
 2. The mechanical circulatory support system of claim 1,wherein the rotor comprises impeller blades, wherein the rotor isradially levitated and driven by the control unit.
 3. The mechanicalcirculatory support system of claim of claim 1, wherein the control unitis further configured to: receive an update; verify the update; andstore the update in place of an un-updated application, all while therotor is temporarily stopped.
 4. The mechanical circulatory supportsystem of claim 3, further comprising restarting movement of the rotorafter the update has been verified.
 5. The mechanical circulatorysupport system of claim 1, wherein the rotor is temporarily stopped fora period of time less than forty-five seconds.
 6. The mechanicalcirculatory support system of claim 1, wherein the rotor is temporarilystopped for a period of time less than one minute.
 7. The mechanicalcirculatory support system of claim 1, wherein the rotor is temporarilystopped for a period of time less than five minutes.
 8. The mechanicalcirculatory support system of claim 1, further comprising a firstapplication comprising parameters for rotor control and a secondapplication comprising parameters for rotor control, wherein theprocessor is configure d to not erase one of the first and secondapplications during the update process.
 9. The mechanical circulatorysupport system of claim 8, wherein the control unit comprises flashmemory comprising a plurality of partitions.
 10. The mechanicalcirculatory support system of claim 9, wherein at least two of thepartitions each comprise an application including parameters forcontrolling the operation of the blood pump.
 11. The mechanicalcirculatory support system of claim 10, wherein the parameters define atleast one of pump speed and pulsatile operation.
 12. The mechanicalcirculatory support system of claim 1, wherein the controller comprisesan external controller configured to wirelessly transmit updateinformation or an external controller having as driveline coupled to theimplantable pump to transmit update information.
 13. An implantableblood pump comprising: a rotary motor; a control unit communicativelycoupled with the rotary motor and comprising memory having a pluralityof partitions, wherein a plurality of applications are loaded in atleast some of the partitions, wherein the control unit is configured to:control the motion and position of the rotary motor; and temporarilystop the rotary motor in response to a signal initiating an updateprocess.
 14. The implantable blood pump of claim 13, wherein each of theapplications of the plurality of applications are uniquely associatedwith a datum and data identifying the time of the loading of each theapplications into the partition.
 15. The implantable blood pump of claim14, wherein the control unit is configured to select one of theapplications of the plurality of applications for replacement.
 16. Theimplantable blood pump of claim 15, wherein the one of the applicationsof the plurality of applications is selected for replacement if: thedatum associated with the application does not match a datum generatedby the control unit; or if the application data identifying the time ofthe loading of the application into the partition identifies theapplication as the earliest loaded application of the plurality ofapplications.
 17. The implantable blood pump of claim 16, wherein theplurality of applications comprises a first application and a secondapplication, and wherein the first and second applications compriseinstructions for controlling the operation of the rotary motor.
 18. Theimplantable blood pump of claim 17, wherein the control unit isconfigured to not erase one of the plurality of applications during theupdate process.
 19. The implantable blood pump of claim 13, wherein thecontrol unit is configured to direct the restart of movement of therotor after the completion of the update.
 20. The implantable blood pumpof claim 19, wherein the update is completed after one of: verificationof the update; and a passage of a predetermined amount of time.
 21. Theimplantable blood pump of claim 20, wherein the rotary motor isrestarted according to one of the plurality of applications after thepassage of a predetermined amount of time.
 22. The implantable bloodpump of claim 13, wherein the rotary motor is located within a firstimplantable housing and the control unit is located in a secondimplantable housing.